KR100941896B1 - Method and apparatus for providing configurable layers and protocols in a communications system - Google Patents

Abstract

The layers and protocols of an air interface layering architecture are designed to be modular and can be modified and upgraded to support new features, perform complex tasks, and implement additional functionality. Prior to commencement of data communication between a first entity (e.g., an access terminal) and a second entity (e.g., a radio network), a set of layers and/or protocols is selected for negotiation. For each selected layer and protocol (i.e., each attribute), a list of attribute values considered acceptable to the first entity is determined. The selected attributes and their associated attribute values are sent from the first entity and, in response, a list of processed attributes and their associated lists of processed attribute values arc received. Each list of processed attribute values includes attribute values considered acceptable to the second entity. The layers and protocols in the first entity are then configured in accordance with the received list of processed attributes and their associated processed attribute values. Other features related to configurable layers and protocols are also provided.

Description

METHOD AND APPARATUS FOR PROVIDING CONFIGURABLE LAYERS AND PROTOCOLS IN A COMMUNICATIONS SYSTEM}

The present invention relates to wireless communication. More specifically, the present invention relates to a method and apparatus for providing configurable layers and protocols in a communication system.

Code division multiple access (CDMA) modulation technology is one of several techniques that facilitates multiple existing communication with system users. Other multiple access communication system technologies are known, such as time division multiple access (e.g., TDMA and GSM), frequency division multiple access (FDMA), and AM modulation schemes such as amplitude companded single sideband (ACSSB), but the spread of CDMA Spectrum modulation techniques have significant advantages over these other modulation techniques for multiple access communication systems. "SPREAD SPECTRUM MULTIPLE ACCESS COMMUNICATION SYSTEM USING SATELLITE OF TERRESTRIAL," US Patent No. 4,901,307 entitled "REPEATERS" and US Patent No. 5,103,459 entitled "SYSTEM AND METHOS FOR GENERATING SIGNAL WAVEFORMS IN A CDMA CELLULAR TELEPHONE SYSTEM", filed April 7, 1992.

In general, CDMA systems are designed to conform to one or more specific CDMA standards. Examples of such CDMA standards are "TIA / EIA / IS-95-A Mobile Station-Base Station Compatibility Standard for Dual-Mode Wideband Spread Spectrum Cellular System", "TIA / EIA / IS-95-B Mobile Station-Base Station" Compatibility Standard for Dual-Mode Wideband Spread Spectrum Cellular System "," Recommended Minimum Performance Standard for Dual-Mode Spread Spectrum Cellular and PCS Mobile Stations "TIA / EIA / IS-98-A, -B, and -C standards , And "The cdma2000 ITU-R RTT Candidate Submission". New CDMA standards continue to be proposed and adopted for use.

Each CDMA standard specifies a radio interface protocol used by each standard that supports communication between communication devices (eg, between an access terminal and a wireless network). The air interface protocol may define a mechanism by which a particular function is to be performed, and may include a number of protocols that enable the implementation of various functions.

By convention, each CDMA standard employs a specific air interface protocol that performs a number of functions and is identified by a unique revision number. In general, new functions can be implemented by defining new attributes, messages, and state machines within the framework of existing air interface protocols. A new air interface protocol is then defined that includes new attributes, messages, and state machines, along with other predefined attributes, messages, and state machines. Similarly, if an existing protocol is changed or updated, a new air interface protocol is defined and a new revision is assigned.

By convention, each communication device (eg, each access terminal and wireless network) is designed to support one or more complete revisions of the air interface protocol. Since the entire radio interface protocol is defined by a single revision, if each communication device wishes to support a function in that revision, then each communication device must support all of the requested functions in that particular revision. In general, communication devices are designed to support one or more revisions (eg, range of revisions). Then, using one of the commonly supported air interface protocol revisions, communication between the access terminal and the wireless network is realized.

The desire for increased radio functionality and capacity has made the air interface protocol much more complex. In particular, air interface protocols have evolved to perform many complex functions, including voice communications, data transmission, and the like.

Conventional methods for defining new revisions to each new air interface protocol have been adapted to the simpler protocol of the original CDMA system design. As the number of functions and their complexity increase, conventional methods are cumbersome and inadequate. In addition, conventional methods are not easy to support implementing additional functionality in existing air interface protocols or implementing subsets of functionality in air interface protocols. Therefore, there is a great need for an air interface protocol structure that efficiently supports the implementation of various functions.

Embodiments of the present invention provide a method in which data communication between a first entity (eg, an access terminal) and a second entity (eg, a data network) configures a layer or protocol prior to initiation. According to the method, one or more layers and a set of one or more protocols are selected for negotiation, each of the selected layers and protocols corresponding to an attribute to be negotiated between the first entity and the second entity. For each of the optional attributes, a list of optional attribute values is determined, the list comprising one or more attribute values deemed acceptable at the first entity. A list of optional attributes and their associated attribute values are sent from the first entity, and in response, a list of process attributes and a list of process attribute values associated with them are received. Each list of processing attribute values includes one or more attribute values that are deemed acceptable at the second entity. Then, according to the received list of process attributes and their associated process attribute values, the layer and protocol of the first entity are constructed. In an embodiment, each processing attribute is associated with one processing attribute value. In an embodiment, if a corresponding processing attribute value is not received at the first entity, the layer and protocol of the first entity are configured with their default values.

The first or second entity, or both, may include (1) an inactive state indicating inactivity before session negotiation, (2) an initialization state indicating session negotiation for a list of optional attributes, and (3) the first and second entities. It is possible to implement a state machine with multiple states, including an open state indicating communication activity therebetween. The initialization state may be implemented to include (1) an access terminal initialization state indicating session negotiation for an attribute selected by the access terminal, and (2) a wireless network initialization state indicating session negotiation for an attribute selected by the wireless network. have.

A communication session between the first and second entities may be established by sending an open-request message from the first entity and receiving an open-response message indicating acceptance or rejection of this request. Open-request and open-response messages may be sent and received by a common communication channel.

Optional attributes and attribute values associated with them may be transmitted by one or more configuration-request messages, and processing attributes and attribute values associated with them may be received by one or more configuration-response messages. The message may be identified by the entity identifier assigned to the first entity. Each element of the list of selection attribute values may be sorted in an order based on a preference of the first entity, and the elements of the received configuration-response message may be received in an order corresponding to the order of the elements of the configuration-request message. The configuration information can be transmitted and received by a dedicated communication channel.

The first and second entities may communicate by default layer and protocol before the configuration of the compromised layer and protocol is completed. In one implementation, if both the first entity and the second entity select a set of attributes to be compromised, the compromise for the set selected by the first entity is completed prior to the compromise of the set selected by the second entity.

Another embodiment of the present invention provides a method for providing a configurable layer or protocol, or both in a communication system. According to the method, a set of default layers and protocols is maintained for communication between the first entity and the second entity. Similarly, one or more configurable layers and one or more configurable protocols, or a set of combinations thereof, are maintained for communication, each of the configurable layers and protocols corresponding to attributes that can be negotiated between the first and second entities. A set of configuration messages can be provided and used to send and receive configuration information related to each configurable attribute. A state machine is provided to track the operating state of the first entity. The state machine may include the steps and sub-steps described above.

The set of default layers and protocols generally includes a configuration protocol that is used to send and receive messages that support the negotiation and configuration of a configurable set of attributes. The configuration message may be implemented at the session layer of the communication system. Each configuration message may include an entity identifier that identifies the first entity and a transaction identifier that identifies a particular moment in the configuration message.

Yet another embodiment of the present invention provides an access terminal of a spread spectrum communication system having a controller, an encoder, a modulator, and a transmitter. The controller receives and processes the data (eg, call and signal data), the encoder encodes the processing data, the modulator modulates the encoded data, and the transmitter converts the modulated data into an analog signal suitable for transmission to the transmission medium. To convert. The controller implements a set of layers and protocols used to support data transmission, with one or more layers and one or more protocols, or a combination thereof, that can be configured by the access terminal prior to data transmission.

The access terminal may further comprise a receiver, a demodulator, and a decoder. The receiver receives the forward link signal, the demodulator demodulates the received forward link signal, the decoder decodes the demodulated signal, and the controller uses one or more configurable layers and protocols based on the portion of the decoded data from the decoder. Configure.

The present invention also provides a method and apparatus suitable for implementing configurable layers and protocols in a wireless network.

The present invention provides techniques used to implement configurable layers and protocols in communication systems. The layers and protocols of the air interface layering architecture are modular, and can be changed and upgraded to support new features, perform complex tasks, and implement additional functionality. The access terminal and the wireless network can communicate using layers and protocols commonly supported by both, and this determination is made upon opening a communication session. The basic set of layers and protocols supported by access terminals and wireless networks ensure a minimum level of compatibility.

DESCRIPTION OF EMBODIMENTS The following clearly describes the features, features, and advantages of the present invention with reference to the drawings, in which like elements are designated by like reference numerals in the drawings.

1 is a diagram of a spread spectrum communication system 100 supporting multiple users. Within system 100, a set of access terminals 110A-110C communicate with a wireless network by over-the-air links over a set of base station transceivers (BSTs) 112A-112F. Each base station transceiver 112 is connected to a base station controller (BSC) 114 and a visitor location register (VLR) 116. In addition, the base station controllers 114A and 114B and the base station transceiver 112 can be directly connected to each other, as indicated by a dotted line in FIG. 1.

As used herein, an access terminal is a device that provides data and / or voice connections to a user. The access terminal may be a stand-alone, self-contained data device, such as a cellular telephone, personal digital assistant (PDA), or other form of standalone data device. The access terminal can also be a unit or module configurable to connect to a computing device, such as a desktop or laptop personal computer. As used herein, a wireless network is a network equipment (eg, base station transceiver 112 of FIG. 1) that provides data and / or voice connections between a data network (eg, a PSDN such as the Internet) and an access terminal. ), Base station controller 114, and visitor location register 116. As explained below, connections are generally provided in the link layer.

2 is a block diagram of an embodiment of a wireless network 210 and an access terminal 250. In the wireless network 210, call data from the buffer 212 and control data from the control system 214 are provided to an encoder 216 that encodes the data in a particular encoding format. The encoding format can be used commonly for CDMA systems such as cyclic redundancy check (CRC) encoding, convolutional encoding, serial-connected coding, Reed-Solomon block encoding, Walsh covering, PN spreading, and the like. It may include. The encoded data is provided to a modulator 218 that modulates the data with a particular modulation format, such as quadrature phase shift keying (QPSK), offset QPSK, and the like. Transmitter 220 receives the modulated data, converts it into an analog signal, adjusts the signal, and transmits this signal wirelessly by duplexer (D) 222 and antenna 224.

At access terminal 250, a transmit signal is received by antenna 252, routed through duplexer D 254, and provided to receiver 256. Receiver 256 adjusts this signal and provides an adjustment signal to demodulator 258. Signal conditioning may include filtering, amplification, frequency conversion, and the like. Demodulator 258 demodulates the adjustment signal in a demodulation format that is complementary to the modulation format used in wireless network 210. Decoder 260 receives demodulated data and decodes it as a decoding format that is complementary to the encoding format used in wireless network 210. The decoded data is then provided to the controller 262.

Call and control data transmission from the access terminal 250 to the wireless network 210 is caused by complementary signal paths. Call data from the buffer (not shown in FIG. 2) and control data from the controller 262 are encoded by the encoder 264, modulated by the modulator 266, adjusted by the transmitter 268, and Routed through duplexer 254 and transmitted by antenna 224. In the wireless network 210, the transmitted signal is received by the antenna 224, routed through the duplexer 222, adjusted by the RF receiver 226, demodulated by the demodulator 228, and a decoder ( Decoded by 230 and provided to control system 214.

As used herein, forward transmission means transmission from the wireless network 210 to the access terminal 250 and reverse transmission means transmission from the access terminal 250 to the wireless network 210. The demodulation and decoding format on the reverse path may generally be different than that on the forward path.

For many communication systems, communication between an access terminal and a wireless network is realized by a set of "layers" that define the mode of operation, the features supported, and the capabilities of the communication system. Each layer consists of one or more layer protocols (or simply protocols) that perform the functions of the layer. Each layer communicates with a layer above itself, a layer below itself, or both, by a defined interface.

Originally, CDMA systems conforming to the IS-95 standard support a single air interface protocol that specifies the layer and its protocol. In some respects, the IS-95 standard lacks the ability to separate protocols by function. The original wireless interface protocol has been changed many times to support additional features, such as enhanced Medium Access Control (MAC). In order to implement additional functionality, the necessary changes are made to the affected layer in the original air interface protocol, and the changed air interface protocol is identified by the new revision number (and is generally defined by the new standard). In general, the modified air interface protocol retains most of the structure of the original air interface protocol (e.g., the same data frame structure, the same frame length, etc.) in order to maintain maximum compatibility with existing systems and standards.

Once adopted and the access terminal and protocol are designed to support the new air interface protocol, the air interface protocol can be executed by both. This method of creating a new air interface protocol does not allow easy implementation of new functions and features in CDMA systems.

According to one aspect of the present invention, layers and their protocols are designed in a modular manner that can change or update each layer (or protocol) without having to change the remaining layers (or protocols). This can be achieved to some extent by defining and maintaining interfaces between layers so that new functionality can be easily supported. In addition, the modular design allows for isolated changes of layers and their protocol (s).

Each layer includes one or more protocols that perform the functions of that layer. According to another aspect of the present invention, the protocol (s) of a particular layer may be individually negotiated between the access terminal and the wireless network (eg, at the start of a communication session). Although the access terminal and the wireless network each can be designed to support a different set of protocols, they can still communicate with each other by protocols common to both. The compromised layer and protocol features allow flexibility in the design and use of different versions of the air interface protocol without having to explicitly define or retain each change as a new air interface protocol, as has been done in the past.

3 is a diagram of an embodiment of an air interface layering structure 300 supported by the present invention. As shown in FIG. 3, the layered structure 300 includes: (1) physical layer 310, (2) medium access control (MAC) layer 314, (3) security layer 316, Seven layers of (4) access layer 318, (5) session layer 320, (6) stream layer 322, and (7) application layer 324. For a better understanding of the invention, the main functions of each layer are briefly described below.

The physical layer 310 defines the "physical" characteristics of the transmission between the access terminal and the wireless network. These physical characteristics may include, for example, the channel structure for the forward and reverse links, transmission frequency, output transmission power level, modulation format, encoding scheme, and the like.

The MAC layer 314 defines the procedure used to transmit and receive data above the physical layer 310.

Security layer 316 provides security services, which may include, for example, authentication and encryption services.

The connection layer 318 provides wireless link connection establishment and maintenance services.

Session layer 320 provides layer and protocol negotiation, protocol configuration, and stateful services. Session layer 320 is described in more detail below.

Stream layer 322 provides multiplexing of various application streams. In a specific embodiment, the communication system supports four application streams, named streams 0 to 3. In an embodiment, stream 0 is used for the signal between the access terminal and the wireless network, stream 1 is used for packet data transmission, and stream 2 and stream 3 are used for other applications. As shown in FIG. 3, a signal stream (eg, stream 0) is supported by Signaling Link Protocol (SLP) 330 and High Data Rate Messaging Protocol (HMP) 332, and a packet data stream (eg, Stream 1) is supported by RLP (Radio Link Protocol) 340 and PPP (Point to Point Protocol) 342. In an embodiment, if stream 0 and stream 1 are not negotiated between the access terminal and the wireless network, the default signal stream (ie, default HMP / SLP) is used as the default for stream 0, and the default packet service (ie, default PPP). / RLP) is used as the default for stream 1.

SLP 330 provides a reliable "best-acting" delivery mechanism for signaling messages, and HMP 332 provides a message transmission service for signaling messages. RLP 340 provides retransmission and duplicate data detection for specifically defined data streams, and details an implementation in IS-707. It is possible to design and use different implementations of RLP 340 than described in IS-707, which is within the scope of the present invention. If RLP 340 is used in a default packet service context, RLP 340 may be defined to carry PPP packets. PPP 342 provides framing and multi-protocol support and is described in detail in "The Point-to-Point Protocol (PPP)" (RFC 1661, July 1994) by W. Simpson. The protocol that predominantly executes PPP 342 can perform various network management tasks as well as carry call data.

3 illustrates a specific embodiment of a layered structure supported by the present invention. In addition, other layering structures with additional layers, fewer layers, or different layers may be supported by the present invention.

4A-4C each illustrates an HDR channel structure 410, a forward channel structure 420, and a reverse channel structure 440 supported by a communication system (eg, the communication system 100 of FIG. 1). It is a figure of a specific Example. The HDR channel structure 410 includes a forward channel structure 420 used to transmit data from the wireless network to the access terminal and a reverse channel structure used to transmit data from the access terminal to the wireless network. The forward and reverse channel structures are designed to provide the necessary functionality, and each channel structure is designed based on specific attributes of data transmission on the forward or reverse link.

4B is a diagram of an embodiment of a forward channel structure 420. In this embodiment, the forward channel structure 420 includes a pilot channel 422, a MAC channel 424, one or more call channels 426, and one or more control channels 428. MAC channel 424 also includes a forward activity channel 432, a reverse activity channel 434, and a reverse power control channel 436. These channels can be designed in a variety of ways, which are within the scope of the present invention. Pilot, MAC, and control channels are "common" channels shared by multiple access terminals in communication with a wireless network. The call channel (s) are the "dedicated" channel (s) assigned to the access terminal at the establishment of the session.

4C is a diagram of an embodiment of reverse channel structure 440. In this embodiment, the reverse channel structure 440 includes one or more call channels 442 and an access channel 444. In addition, the call channel (s) 442 include a pilot channel 452, a MAC channel 454, and one or more data channels 456. MAC channel 454 also includes a reverse rate indicator channel 462 and a data rate control channel 464. Access channel 444 also includes pilot channel 472, MAC channel 474, and one or more data channels 476. The MAC channel 474 can further include a reverse rate indicator channel 478. In addition, these channels can be designed in a variety of ways, which are within the scope of the present invention. As in the case of a forward channel structure, the call channel (s) are "dedicated" channel (s), and the access channel is a "common" channel shared with other access terminals.

Many terms are used to describe the present invention, which terms are defined as follows.

Session refers to the shared operating state between the access terminal and the wireless network. The shared operating state stores protocols and protocol configurations that can be negotiated and used for communication between the access terminal and the wireless network. According to one aspect of the present invention, when a session is established, layers, protocols, and protocol configurations may be negotiated between the access terminal and the wireless network, and in some implementations, may be re-negotiated at any time during the session. In an embodiment, except for the establishment of a session, the access terminal does not have an open session and cannot communicate with the wireless network (ie, the access terminal can communicate with the wireless network for a special purpose of opening a session).

A connection is a particular state of radio-link to which an access terminal is assigned dedicated radio-link resources (eg, forward call channel, reverse call channel, and associated MAC channel). During any particular session, the access terminal and the wireless network can open and close the connection several times. In an embodiment, except establishing a session, there is no connection without a session.

A stream is a transmission channel used to transmit specific application information. The stream may be defined to convey signal information, call data, other forms of data, or a combination thereof. Access terminals and wireless networks can be designed to support simultaneous transmission of multiple streams, and are generally so designed. The stream can be used to convey data or other applications with different quality of service (QoS) requests.

FIG. 5 is a diagram of a specific embodiment of the layering structure layer and protocol thereof of FIG. 3, which is a design that supports the HDR channel structure 410 of FIGS. 4A-4C. As shown in FIG. 5, each layer includes one or more protocols that perform the functions of the layer. The protocol uses signaling messages and / or headers to convey information to other entities on the other side of the radio link. 5 illustrates several protocols included in the layer of the layered structure 300.

In the embodiment shown in FIG. 5, the MAC layer 314 includes a control channel MAC protocol 514A, a forward call channel MAC protocol 514B, an access channel MAC protocol 514C, and a reverse call channel MAC protocol 514D. do. Control channel MAC protocol 514A provides a procedure used by the wireless network transmitting control channel 428 and the access terminal receiving control channel 428. The forward call channel MAC protocol 514B provides a procedure used by the wireless network transmitting the forward call channel 426 and the access terminal receiving the forward call channel 426. The access channel MAC protocol 514C provides a procedure used by an access terminal transmitting an access channel 444 and a wireless network receiving an access channel 444. And, the reverse call channel MAC protocol 514D provides a procedure used by an access terminal transmitting the reverse call channel 442 and a wireless network receiving the reverse call channel 442.

Security layer 316 includes zero or more security protocols designed to prevent fraudulent transmission of signals. In an embodiment, security layer 316 includes a basic security protocol (not shown in FIG. 4) that prevents service-fraud and ID-fracture. Sensitive data communications can generally be protected using end-to-end authentication and encryption, and no additional security at security layer 316 is generally required. However, it provides an interface so that various security protocols can be attached as needed.

The connection layer 318 includes a radio link management protocol 518A, an initialization state protocol 518B, an idle state protocol 518C, a connection state protocol 518D, an idle state monitoring protocol 518E, and a connection state monitoring protocol 518F. ), Packet aggregation protocol 518G, routing update protocol 518H, and overhead message protocol 518I. The radio link management protocol 518A provides overall state machine management to follow while the access terminal and the wireless network are connected. The initialization state protocol 518B provides a procedure that an access terminal should follow to acquire a wireless network and a procedure that a wireless network should follow to support network acquisition. Idle state protocol 518C provides a procedure that the access terminal and the wireless network should follow when the connection is not open. The connection state protocol 518D provides a procedure that the access terminal and the wireless network should follow when the connection is opened. Idle state monitoring protocol 518E provides a monitoring procedure that the access terminal and the wireless network should follow when the connection is not open. The connection state monitoring protocol 518F provides a monitoring procedure that the access terminal and the wireless network should follow when the connection is opened. Packet aggregation protocol 518G provides transmit prioritizing and packet encapsulation for connection layer 318. The routing update protocol 518H provides a means for maintaining routing between the access terminal and the wireless network. The overhead message protocol 518I then provides a broadcast message that holds information used by the protocol of the connection layer 318.

Session layer 320 includes session boot protocol 520A and session control protocol 520B. The session boot protocol 520A provides an initiation message exchange used to initiate a session and further provides a means of denying an access terminal that does not currently have a session. The initiation message exchange assigns a unicast access terminal identifier (UATI) to the access terminal, and in turn selects a session control protocol that is negotiated to configure the protocol to be used in the session. UATI is also referred to herein as a "terminal identifier." In an embodiment, session boot protocol 520A is non-negotiable.

Session control protocol 520B provides initiation negotiation and configuration of the protocol to be used during the session, and also supports session monitoring and session closure procedures. In an embodiment, session control protocol 520B supports two negotiation steps-initialization negotiation of access terminal (AT) and initialization negotiation of wireless network (RN). In the AT initialization negotiation phase, a negotiation exchange is initiated by the access terminal. This step is generally used to negotiate the protocol to be used in the session and to compromise the configuration for this protocol (eg, authentication key length). In the RN initialization negotiation phase, the negotiation exchange is initiated by the wireless network. This step is generally used to override the default value that will be used by the negotiated protocol. In addition, session control protocol 520B can provide a session keep alive mechanism. In an embodiment, according to the session revival mechanism, if nothing flows between the access terminal and the wireless network for some time, one entity sends a revival message to the remaining entity to which it responds.

The session boot protocol 520A and the session control protocol 520B are described in detail below.

Stream layer 322 includes stream protocol 522A. In the transmit direction, the stream protocol 522A appends a stream header to the data packet and guarantees that the packet is in octet alignment. In the receive direction, the stream protocol 522A removes the stream header and forwards the packet to the appropriate application.

In an embodiment, protocols are defined by their interface and protocol state. In a specific embodiment, four types of interfaces are defined, including (1) headers and messages, (2) commands, (3) indications, and (4) common data. In the following description, the term "entity" is used to refer to either an access terminal or a wireless network.

The header and message are used for communication between the protocol running in one entity and the same protocol in the other entity.

Instructions are used by a higher layer protocol in the same entity to obtain services from a lower layer protocol. For example, an instruction can be used as primitives by a higher layer to cause the protocol at the lower layer to take some action (eg, to abort any ongoing access attempts currently in progress). . In an embodiment, a command may be sent between protocols of the same layer, but is limited in one direction (ie, an entity receiving a command from a particular protocol is prohibited from sending the command to the remaining entities in the same protocol). .

Instructions are used by lower layer protocols to convey information about the occurrence of an event (eg, to provide a notification when an event occurs). In an embodiment, higher layer or same layer protocols may be registered to receive an indication. In an embodiment, the indication between protocols of the same layer is limited in one direction (ie, if protocol A is registered to receive instructions from protocol B, protocol B is prohibited from registering to receive instructions from protocol A). .

Public data is used to share information between protocols in a controlled manner. Protocols may allow some of the data they generate or receive via messages to benefit other protocols. Public data can be shared between protocols of the same layer as well as between protocols of different layers.

The protocol state is used to identify a particular operating state of a particular protocol. Each protocol state is associated with a particular set of behavior characteristics that may depend on, for example, operating conditions, the environment of the entity (eg, whether a connection is open, whether a session is open, etc.), and other factors. May be related. The transition between protocol states is triggered by the occurrence of a particular event that is also captured by the operating state. Examples of events that can lead to state transitions include receipt of messages, instructions from higher layer protocols, instructions from lower layer protocols, and expiration of timers.

The wireless network can communicate with multiple access terminals simultaneously. The wireless network communicates with the wireless network and then instantiates a signaling protocol for each access terminal that maintains a protocol state machine for the access terminal. A wireless network can have multiple independent instances of a signaling protocol, each with its own independent state machine.

In an embodiment, an inactive state, an open state, and a closed state are provided for each of a plurality of protocols. If the protocol does not function at a certain time, it enters an inactive state. For example, the access channel MAC protocol of an access terminal enters an inactive state when it has an open connection. The open state indicates that the session or connection (applicable to the protocol) is open, and the closed state indicates that the session or connection is closed. In an embodiment, all states of a particular protocol may be individually labeled except inactive, but these are collectively referred to as active. For example, the forward call channel MAC protocol can be designed to have three states: inactive, variable rate, and fixed rate states, which are called active states.

Each protocol supports a set of commands that facilitate communication with other protocols. Some common commands supported by many protocols include activation, deactivation, opening, and closing. Activation instructs the protocol to transition from an inactive state to some other state. Deactivation commands the protocol to transition to an inactive state. Open (or close) instructs the protocol to perform a function related to opening a session (or closing) or opening a connection (or closing).

According to one aspect of the present invention, when a session is established, multiple applications, layers, protocols, or configurations (ie, for applications, layers, and protocols), or a combination thereof may be compromised. Each stream, layer, and protocol is assigned a unique identifier (hereinafter referred to as Type) that identifies a general stream, layer, or protocol (eg, an access channel MAC protocol). In a specific implementation, the identifier is an 8-bit value. Layering (as shown in FIG. 3) may also be compromised.

In an embodiment, the stream, layer, or protocol may further comprise a subtype (eg, a default access channel MAC protocol and one day an extended and extended access channel MAC protocol, etc.) identifying the specific moment of that layer or protocol. May be related.

The hierarchical structure shown in FIG. 3 supports various applications. According to one aspect of the present invention, for minimal compatibility, a set of default applications supported by all access terminals and wireless networks is defined. In an embodiment, the default application includes a default signal application and a default packet application. The default signaling application provides a means for sending messages between the protocol of one entity and the same protocol of another entity. The default packet application provides a PPP octet stream between entities.

In an embodiment, the default signaling protocol is (1) a messaging protocol (eg, HDR messaging protocol) and (2) a link layer protocol (eg, signaling link protocol that provides message fragmentation, retransmission, and duplicate data detection). (SLP)). In an embodiment, the default packet application includes (1) PPP providing a PPP octet stream (ie, as defined by IETF RFC 1661) and (2) link layer protocol providing octet retransmission and duplicate data detection (eg For example, radio link protocol (RLP).

According to one aspect of the invention, the application to be used, the stream, layer, protocol, and configuration to which the application will be delivered, may be negotiated as part of session negotiation. In an embodiment, session negotiation is implemented at the session layer. According to another aspect of the invention, each access terminal and wireless network is designed to support a basic layering structure and a basic set of protocols. At the start of communication between the access terminal and the wireless network, session negotiation is performed and a basic set of protocols and additional protocols can be negotiated between entities.

The set of default applications, layers, protocols, and configurations is used to support communication between entities until the protocol is compromised. Each layer contains zero or more default protocols. The default overhead signaling protocol message can be used to exchange information related to the default layer, protocol, and configuration. The access terminal and the wireless network use the default settings until session negotiation is complete to apply the compromised layer, protocol, and configuration for use in subsequent communications.

6A is a state diagram of an embodiment of a session boot protocol (eg, session boot protocol 520A of FIG. 5) for an access terminal, illustrating an inactive state 610, an initialization state 612, and a session state 614. Include. As shown in FIG. 6A, the session boot protocol for an access terminal transitions from initiation state to inactive state 610 to open a session. In an inactive state 610, there is no communication between the access terminal and the wireless network. Upon sending or receiving the activation message, the protocol transitions to an initialization state 612 where the access terminal and the wireless network exchange open-request and open-response messages. The protocol transitions back to inactive state 610 if the received open-response message indicates that the request was denied, and to session state 614 if the request is accepted. By exchanging open-request and open-response messages, an access terminal is assigned a UATI (ie, terminal identifier), and a session control protocol is selected for use in session negotiation. In session state 614, the session is in the process of being negotiated by the session control protocol selected in the open, or initialized state 612. The protocol transitions back from the session state 614 to the inactive state 610 upon transmission or reception of a closure message, or upon receipt of a reject message from the wireless network.

6B is a state diagram of a session boot protocol embodiment for a wireless network including an inactive state 620, an initialization state 622, and a session state 624. The session boot protocol for the wireless network enters an inactive state 620 upon receipt of an instruction to open a session. The protocol transitions from inactive state 620 to initialization state 622 upon receipt of an open-request message from an access terminal. The open-request message is processed, and the protocol transitions back to the inactive state 620 upon transmission of the open-response message indicating the rejection of the open request, and the session state (when receiving the open-response message indicating the acceptance of the request). 624). The protocol reverts from session state 624 to inactive state 620 upon transmission or receipt of a closure message.

FIG. 6C illustrates a session control protocol (eg, session of FIG. 5) for an access terminal, including an inactive state 630, an AT initialization state 632, an RN initialization state 634, and an open state 636. Control Protocol 520B) is a state diagram of an embodiment. The session control protocol for the access terminal transitions from initiation state to inactive state 630 for session negotiation. In the inactive state 630, the protocol waits for an activation command and, upon receipt or transmission of the activation command, transitions to AT initialization state 632. In the AT initialization state 632, the negotiation is performed at the initiation of the access terminal, and upon completion of the negotiation performance (eg, as indicated by the transmission of the configuration-complete message), the protocol enters the RN initialization state. Transition to 634. In the RN initialization state 634, the negotiation is performed at the initiation of the wireless network, and upon completion of the negotiation performance (eg, as indicated by the receipt of the configuration-complete message), the protocol enters the open state 636. Transition In the open state 636, the session is open and can be used to exchange application calls (eg, for streams 0 to 3) between the access terminal and the wireless network. The protocol reverts from the open state 636 to the inactive state 630 upon closing of the session (eg, upon receipt of a close message).

6D is a state diagram of a session control protocol embodiment for a wireless network including an inactive state 640, an AT initialization state 642, an RN initialization state 644, an open state 646, and a closed state 648. The session control protocol for the wireless network transitions to inactive state 640 for session negotiation. In the inactive state 640, the protocol waits for an activation command and, upon receipt or transmission of the activation command, transitions to the AT initialization state 642. In AT initialization state 642, an access terminal initialization negotiation is performed, and upon completion of the negotiation performance (eg, as indicated by receipt of a configuration-complete message), the protocol transitions to RN initialization state 644. do. In the RN initialization state 644, wireless network initialization negotiation is performed, and upon completion of the performance (eg, as indicated by the transmission of the configuration-complete message), the protocol transitions to the open state 646. In the open state 646, the session is open and can be used to exchange application calls between the access terminal and the wireless network. The protocol transitions back from the open state 646 to the inactive state 640 upon receipt of the closure message and transitions to the closed state 648 upon transmission of the closure message. From the closed state 648, the protocol transitions back to the inactive state 640 upon receipt of the closed message or expiration of the timer.

For simplicity, not all transitions are shown in FIGS. 6A-6D. For example, inactive transitions are not shown in FIGS. 6A and 6B, and failure transitions are not shown in FIGS. 6C and 6D.

7A is a flowchart of a specific implementation of a session opening step 610. The protocol of session open step 610 allows an access terminal to request and receive an access terminal identifier using an open-request message and an open-response message. The access terminal initiates a message exchange by sending an open-request message over a reverse common channel (eg, access channel 444 of FIG. 4C) at block 710, and identifies itself with a random access terminal identifier. The wireless network receives and negotiates an open-request message, at block 712.

At block 714, the wireless network determines to accept or reject the open request. If the session request is accepted, the wireless network assigns an access terminal identifier to the access terminal at block 716 and generates an open-response message that includes the assigned identifier. The access terminal identifier is used by the access terminal for the duration of the session. Alternatively, if the session request is denied, the wireless network generates, at block 718, an open-response message containing the reason for denial. The open-response message also includes a random access terminal identifier extracted from the open-request message received from the access terminal. Then, at block 720, an open-response message is transmitted to the access terminal via the forward common channel (eg, control channel 428). In an embodiment, the message of session open step 610 is performed by the (default) session protocol.

As shown in FIG. 6B, session configuration step 620 includes session layer / protocol negotiation sub-step 622, session layer / protocol configuration sub-step 624, and session layer / protocol activation sub-step 626. It includes. Hereinafter, these sub-steps will be described in detail.

7B is a flowchart of a specific implementation of session layer / protocol negotiation sub-step 622. The protocol of sub-step 622 allows one or more configuration-request messages and configuration-response messages to negotiate mutually acceptable layers, protocols, and configurations with the access terminal and the wireless network.

Initially, the access terminal identifies, at block 730, the set of layers and protocols (or layers / protocols, these are identified by their type) to be negotiated. For each of the selected layers and protocols, the access terminal identifies, at block 732, a set of acceptable configurations (they are identified by subtypes). The access terminal then generates, at block 734, one or more configuration-request messages and transmits over the reverse dedicated channel to the wireless network.

Each configuration-request message includes one or more types that identify one or more corresponding layers / protocols to be negotiated. For each type, the message further includes a list of one or more acceptable subtypes listed in decreasing order of preference. In an embodiment, to simplify message processing, each configuration-request message is one or more complete and ordered subtype lists (ie, the subtype list is not separated within the configuration-request message and multiple configuration-request messages are generated). It is not separated through).

The wireless network receives, at block 736, the configuration-request message (s) and, at block 738, identifies a list of each type and associated subtype. For each approved type of configuration-request message, the wireless network selects an acceptable subtype from the relevant list of subtypes already identified as acceptable by the access terminal, at block 740. If the wireless network does not accept the type or does not find an acceptable subtype in the relevant list, the type is skipped. The wireless network then generates and transmits a configuration-response message at block 742 that includes the type (s) processed by the wireless network and the subtype selected for each type. Any type skipped by the wireless network is removed from the configuration-response message. In an embodiment, to simplify processing by the access terminal, the type (s) of the configuration-response message are aligned with each other in the same order as found in the configuration-request message.

The access terminal receives a configuration-response message at block 746 and compares the type (s) of the configuration-response message with the type (s) of the configuration-request message at block 748. For each type of configuration-request message not found in the configuration-response message, the access terminal sets, at block 748, the subtype for that type to a default value. For each type of configuration-response message, the access terminal sets, at block 752, the subtype for that type to the associated subtype found in the received configuration-response message.

In an embodiment, the wireless network declares, at block 744, a configuration failure if it is determined at any moment during the message exchange that the type or subtype selected by the access terminal does not operate.

In an embodiment, the access terminal, at block 754, at any moment during the message exchange,

1) the received configuration-response message does not have an associated configuration-request message;

2) the configuration-response message contains multiple attribute values (ie multiple subtypes) for one attribute (ie type),

3) the configuration-response message contains an attribute not found in the associated configuration-request message;

4) The configuration-response message contains an attribute value not found in the configuration-request message.

5) the configuration-response message contains attributes in a different order than the order of the associated configuration-request message, or

6) If it is determined that the configuration selected by the wireless network is inoperative, declare a configuration failure.

Configuration failures may also be declared based on several other conditions by the access terminal and the wireless network.

If a configuration failure is declared, the side declaring the failure closes the session. The closed-type and closed-subtypes are set to the type and subtype of the link layer protocol, respectively. In an embodiment, if the access terminal and the wireless network cannot agree on the configuration for one or more session layers / protocols, the session is closed.

Once the session layer / protocol negotiation sub-step 622 for a particular layer / protocol is completed, the access terminal and the wireless network enter the session layer / protocol configuration sub-step 624 for that layer / protocol. In sub-step 624, the access terminal and the wireless network determine the configuration of the compromised layer and protocol during the session layer / protocol negotiation sub-step 622. The message for sub-step 624 is conveyed by their respective layer / protocol type.

Session layer / protocol configuration sub-steps for one or more selected layers / protocols may be performed in series or in parallel to speed up the configuration procedure. For enhanced compatibility, wireless networks can be designed to support both serial and parallel configurations, and access terminals can be designed to support either serial or parallel configurations, or possibly both.

Implementation of the configuration sub-step 624 is dependent on the specific layer / protocol to be configured. Various implementations of configuration sub-step 624 may be considered, which is within the scope of the present invention.

7C is a flow diagram of a session layer / protocol activation sub-step 626 embodiment. Upon completion of the session layer / protocol configuration sub-step 624 for all tradeoff layers and protocols, the access terminal and the wireless network enter the session layer / protocol activation sub-step 626. At sub-step 626, the access terminal and the wireless network activate the negotiated session layer and protocol. The message of sub-step 626 is conveyed by the session protocol.

In an embodiment, the access terminal initiates activation sub-step 626 by sending a session-activation-request message on the reverse dedicated channel, at block 780. If an access terminal requests the release of a connection for activation of a negotiated layer and protocol, the access terminal presents this request in a session-activation-request-message. The wireless network receives and negotiates this message at block 782. The wireless network then transmits a session-activated-response message on the forward dedicated channel, at block 784. If disconnection is requested, the wireless network indicates this request in a session-activation-response message.

In block 786, determine whether the access terminal or the wireless network requested the release of the connection to activate the compromised layer and protocol. If disconnection is requested, the access terminal releases the connection, at block 788. Upon release of the connection, the access terminal and the wireless network activate and use the compromised layer and protocol, at block 790. Alternatively, at block 792, determine whether a session-activation-response-message has been received by the access terminal. When a session-activation-response message is received, the access terminal and the wireless network activate and use the negotiated layer and protocol. The access terminal, upon receiving a session-activated-response message at block 794, resends the confirmation message to the wireless network.

If, at block 796, during the session, it is determined that different layers, protocols, and / or configurations have been obtained, at block 798, the current session is terminated and a new session is established.

In an embodiment, session layer / protocol negotiation sub-step 622 may be performed for both selected layers and protocols, and then session layer / protocol configuration sub-step 624 is selected for each of the selected layers and protocols. Is performed. Alternatively, the session layer / protocol negotiation sub-step 622, followed by a session layer / protocol configuration sub-step 624 for the selected layer and protocol, is followed by a specified number of selected layers and protocols (eg, For example, one layer or protocol may be performed (eg, a compromise and configuration sub-step is performed in combination for each layer and protocol).

8 is a message flow diagram of a specific implementation of a session layer / protocol sub-step 622 and a session layer / protocol configuration sub-step 624 initiated by an access terminal establishing a communication link with a wireless network. The access terminal initiates session negotiation by sending the open request message 810 to the wireless network by a common channel (eg, the access channel of FIG. 4, or an access channel of an IS-95 compatible system). The open-request message includes a message identifier and a transaction identifier, each identifying a message and a transaction to the wireless network. The wireless network receives and processes the open-request message and resends the open-response message 812 to the access terminal. The open-response message includes a message and transaction identifier, a result-sign corresponding to the result of the open request, and an access terminal identifier if the request was accepted.

The access terminal and the wireless network then determine the layers and protocols to be negotiated. This is realized by the exchange of messages 820 and 822 over the assigned forward and reverse call channels (e.g., forward call channel 426 and reverse call channel 442 of Figure 4) between the access terminal and the wireless network. Can be. Multiple messages can be sent by the access terminal and the wireless network. The message (s) sent by the access terminal is symbolically represented as message 820 in FIG. 8, and the message (s) sent by the wireless network is symbolically represented as message 822.

In an embodiment, open-request and open-response messages are transmitted by a common channel (eg, access channel and control channel) shared by other access terminals, while negotiation and configuration messages are assigned by the wireless network. It is transmitted by a dedicated channel. Open-request and open-response messages are designed to be short. In general, negotiation and configuration messages are sent by dedicated dedicated channels which are longer and for improved performance (i.e. shorter response time).

Once the layers and protocols have been selected, a compromise is made for each of the selected layers and protocols. In an embodiment, the layers and protocols selected by one entity (eg, access terminal) are first compromised, and then the layers and protocols selected by the other entity (eg, wireless network) are compromised. Entities that are negotiating a particular layer or protocol may send the configuration-request message 830 or 840 to the remaining entities, including a list of one or more selection layers and / or protocols and an acceptable configuration for each of the selection layers and protocols. Send. (The layers and protocols to be negotiated are also called attributes, and configurations are also called attribute values.)

The remaining entity receives the configuration-request message (s) and responds with the corresponding configuration-response message (s) 832 or 842, including the layer and / or protocol to be negotiated and their optional configuration. The exchange of configuration request / response messages continues until both entities accept the compromised attributes. An acknowledgment message 834 or 844 is then sent by the entity initiating the compromise confirming the acceptance of the compromised attribute. If there are additional attributes selected, they are negotiated in a similar manner.

In FIG. 8, negotiation messages 830 and 832 and confirmation message 834 represent messages for one set of attributes (ie, one layer, one protocol, etc.). Another set of messages is sent for each set of attributes selected for negotiation. In the embodiment shown in FIG. 8, the negotiation messages 840 and 842 and the confirmation message 844 for the selected attribute set for negotiation by the wireless network are exchanged after the attributes selected by the access terminal are negotiated.

Upon completion of the protocol negotiation, communication between the access terminal and the wireless network may be performed using the compromised layers and protocols.

According to one aspect of the invention, access terminals and wireless networks are designed to support a basic set of messages. In an embodiment, the access terminal and the wireless network support the messages listed in Table 1, described in detail below.

9A is a diagram of a format embodiment for an open-request message. In this embodiment, the open-request message includes a message-identifier field 910 and a transaction-identifier field 912. In an embodiment, the message-identifier field 910 is an 8-bit field with a value of 0x00 identifying an open-request message, and the transaction-identifier field 912 is also used as each new open-request message sent. 8-bit field with incrementing value.

9B is a diagram of a format embodiment for an open-response message. In this embodiment, the open-response message is a message-identifier field 920, a transaction-identifier field 922, a result-sign field 924, an access-terminal-identifier field 926, and a session-inactivity-timer. Field 928. In an embodiment, the message-identifier field 920 is an 8-bit field with a value of 0x01 that identifies the open-response message, and the transaction-identifier field 922 is also a compromise of the corresponding received open-request message being processed. It is an 8-bit field that holds a value from the identifier field 912. In an embodiment, the result-sign field 924 has a value of 0x00 if the open request is accepted, a value of 0x01 if the open request is rejected for an unknown reason, and a value of 0x02 if the open request is rejected due to lack of resources. Is an 8-bit field with In addition, additional or different values may be generated for the result-signed field.

In an embodiment, the access-terminal-identifier field 926 is a 4-octet field with a value assigned as the access terminal identifier to be used by the access terminal for the duration of the session. If the value of result-sign field 924 is 0x00, then access-terminal-identifier field 926 is set to 0x00000000 and the access terminal ignores this value. In an embodiment, session-inactivity-timer field 928 is an 8-bit field with a value representing the inactivity length of the session in minutes. If the value of the result-sign field 924 is 0x00 indicating acceptance of the open request, the wireless network sets the value of the session-inactivity-timer field 928 to the value from the session inactivity timer being used for the session. do. If the value of the result-sign field 924 is not 0x00 indicating rejection of the open request, the session-inactive-timer field 928 is set to 0x00 and the access terminal ignores this value.

9C is a diagram of a format embodiment for a closure message. In this embodiment, the closure message includes a message-identifier field 930, a transaction-identifier field 932, a reason for closing field 934, an additional information length field 936, and an additional information field 938. In an embodiment, the message-identifier field 930 is an 8-bit field with a value of 0x02 identifying a closure message, and the transaction-identifier field 932 is also 8 with a value incremented with each new outgoing closure message. Bit field. In an embodiment, the closure reason field 934 is a one-octet field with a value identifying the reason for closure, and the additional information length field 936 (in octets) the length of the subsequent additional information field 938. A one-octet field with a value to identify, and the additional information field 938 is a variable length field that holds additional information related to closure. The format for the additional information field 938 is dependent on the particular closure.

9D is a diagram of a format embodiment for a hello message. In this embodiment, the hello message includes an 8-bit message identifier field 940 with a value of 0x03 identifying the hello message.

9E is a diagram of a format embodiment for a configuration-request message. In this embodiment, the configuration-request message includes a type field 950, a message-identifier field 952, a transaction-identifier field 954, and an attribute-list field 956. In an embodiment, the type field 950 is an 8-bit field with a value that identifies the type of protocol to be configured, and the message-identifier field 952 is an 8-bit with a value of 0x04 that identifies the configuration-request message. Field, and the transaction-identifier field 954 is also an 8-bit field whose value is incremented with each new transmission configuration-request message. In an embodiment, the attribute-list field 956 is a variable length field that contains a list of acceptable subtypes for each type to be negotiated, each list element comprising one or more pairs (types, subtypes). . In an embodiment, if the list includes more than one element, the elements are ordered in decreasing order of preference. The receiving entity can determine the length of the configuration-request message by using the length of the message.

9F is a diagram of a format embodiment for a configuration-response message. In this embodiment, the configuration-response message includes a type field 960, a message-identifier field 962, a transaction-identifier field 964, and an attribute-list field 966. In an embodiment, the type field 960 is an 8-bit field with a value that identifies the type of protocol to be configured, and the message-identifier field 962 is an 8-bit with a value of 0x05 that identifies the configuration-response message. Field, the transaction-identifier field 964 is also an 8-bit field that holds the value from the transaction-identifier field 954 of the incoming configuration-request message being negotiated.

In an embodiment, the attribute-list field 966 is a variable length field that includes one (or more possible) acceptable subtypes for each compromised type. The elements of the attribute-list field 966 are (type, subtype) pairs. The attribute-list field 966 does not hold elements that are not found in the corresponding configuration-request message, and the elements of the attribute-list field 966 are sorted in the order found in the corresponding configuration-request message. The receiving entity can also determine the length of the configuration-response message by using the length of the message.

9G is a diagram of a format embodiment for a session-activation-request message. In this embodiment, the session-activated-request message includes a message-identifier field 970, a transaction-identifier field 972, and a disconnect-indicate-indicate field 974. In an embodiment, the message-identifier field 970 is an 8-bit field with a value of 0x06 that identifies the session-activation-request message, and the transaction-identifier field 972 also includes each newly transmitted session-activation-request. An 8-bit field whose value is incremented by the message. In an embodiment, the attach-disconnect-indication field 974 is assigned a value of 0x01 if the access terminal requests to release the connection to transition to session layer / protocol negotiation or configuration sub-step, and otherwise to a value of 0x00. Has a 1-octet field.

9H is a diagram of a format embodiment for a session-activation-response message. In this embodiment, the session-activated-response message includes a message-identifier field 980, a transaction-identifier field 982, and a disconnect-indicate-indicate field 984. In an embodiment, the message-identifier field 980 is an 8-bit field with a value of 0x07 that identifies the session-activation-response message, and the transaction-identifier field 982 is also receiving session-activation-request being processed. An 8-bit field that holds a value from the transaction-identifier field 972 of the message. In an embodiment, the attach-disconnect-indication field 984 may return a value of 0x01 if one of the access terminal or the wireless network requests the release of the connection to transition to the session layer / protocol negotiation or configuration sub-stage. It is a 1-octet field with a value of 0x00.

9A-9H are diagrams of specific embodiments of some messages that may be used in the configuration of applications, layers, and protocols. In addition to the above, additional and / or different messages (eg, activation messages, configuration completion messages, etc.) may also be defined and used, which are within the scope of the present invention. In addition, the message may be designed to have a different (or additional) message format, field, and field format than shown in FIGS. 9A-9H, which is also within the scope of the present invention.

The present invention provides various advantages. First, the modular design of layers and protocols facilitates the modification and upgrade of communication systems that support new features and functions. The access terminal and the wireless network can communicate using layers and protocols commonly supported by both, and this decision is made at the opening of the session. Second, the basic set of layers and protocols supported by the access terminal and the wireless network ensures a minimum level of compatibility between the access terminal and the wireless network. In order for a wireless network to be compatible with this signaling protocol in the future, the wireless network only needs to implement a limited set of functions. For example, the wireless network only needs to be able to send an empty configuration-response message in response to the received configuration-request message. Thus, the signaling protocol of the present invention facilitates the implementation of future configurations, even if not currently required.

The invention can be implemented in a variety of ways, and can be implemented in software, hardware, or a combination thereof. For example, referring back to FIG. 2, the present invention is a combination of software and / or hardware in control system 214 and controller 262, or a combination of other units connected to control system 214 and controller 262. It can be implemented by. The hardware may be implemented in one or more integrated circuits, application specific integrated circuits (ASICs), digital signal processors (DSPs), controllers, microprocessors, or other circuits designed to perform the functions described above.

The invention described herein can be applied to many spread spectrum communication systems. The present invention can be applied to existing CDMA systems and new systems under continuous review. Specific CDMA systems are described in the aforementioned US patent application Ser. No. 08 / 963,386. Other CDMA systems are disclosed in the aforementioned US Pat. Nos. 4,901,307 and 5,103,459.

In the above description of the preferred embodiment, anyone skilled in the art can use the present invention. Those skilled in the art will appreciate that various modifications may be made to these embodiments, and the general principles defined herein may be applied to other embodiments without utilizing the invention capabilities. Thus, the present invention should not be limited to the embodiments shown herein but should be construed in the broadest scope consistent with the principles and novel features disclosed herein.

1 is a block diagram of a spread spectrum communication system supporting multiple users.

2 is a block diagram of a wireless network and access terminal embodiment.

3 is a diagram of an embodiment of an air interface layering structure supported by the present invention.

4A-4C are diagrams of specific embodiments of a high data rate (HDR) channel structure, a forward channel structure, and a reverse channel structure.

FIG. 5 is a diagram of a concrete embodiment of the layers and their protocols for the layered structure shown in FIG.

6A and 6B are each state diagrams of a session boot protocol embodiment for an access terminal and a wireless network.

6C and 6D are each state diagrams of session control protocol embodiments for an access terminal and a wireless network.

7A is a flowchart of a specific implementation of a session open phase.

7B and 7C are flow charts of specific embodiments of the session layer / protocol negotiation sub-step and the session layer / protocol activation sub-step, respectively.

8 is a timing diagram of an embodiment of session layer / protocol negotiation and configuration sub-steps initiated by an access terminal.

9A-9H are diagrams of embodiments of various message formats used in the negotiation and configuration of layers and protocols.

* Description of the main symbols in the drawing

1: spread spectrum communication system 110A, 110B, 110C: access terminal

112: transceiver 112A to 112F: base station transceiver

114: base station controller 116: location register

Claims (38)

delete delete delete delete delete delete delete delete delete delete delete delete delete delete delete delete delete delete delete delete delete delete delete delete delete As an access terminal in a spread spectrum communication system, A controller configured to receive and process data, An encoder connected to the controller and configured to encode processed data from the controller; A modulator connected to the encoder and configured to modulate encoded data from the encoder; And A transmitter connected to the modulator and configured to convert modulated data from the modulator into an analog signal for transmission over a transmission medium, The controller is configured to implement a set of layers and protocols used to support data transmission, and is adapted to negotiate and configure one or more layers and one or more protocols or combinations thereof before the data transmission, Configuration for the one or more layers and one or more protocols or combinations thereof is a response to an attribute negotiated between the access terminal and a wireless network, The controller causes the access terminal to (1) send a first message to the wireless network that includes a plurality of attribute values of the attribute acceptable to the access terminal, and (2) a subset of the plurality of attribute values of the attribute Receive a second message from the wireless network including at least a second message, wherein the subset includes an attribute value of the attribute acceptable to the access terminal and the wireless network, and (3) to the access terminal and the wireless network. The assigned attribute value is selected from the subset, negotiating by assigning an acceptable attribute value to the attribute, The access terminal, A receiver configured to receive a forward link signal; A demodulator connected to the receiver and configured to demodulate the received forward link signal; And A decoder coupled to the demodulator and configured to decode a demodulated signal from the demodulator to produce decoded data, The controller is connected to the decoder and operates to configure one or more of the configurable layers and protocols based on at least a portion of decoded data from the decoder, The receiver is further adapted to receive an open request message, The controller is further adapted to respond to the open request message with an open response message. As an access terminal in a spread spectrum communication system, A controller configured to receive and process data, An encoder connected to the controller and configured to encode processed data from the controller; A modulator connected to the encoder and configured to modulate encoded data from the encoder; And A transmitter connected to the modulator and configured to convert modulated data from the modulator into an analog signal for transmission over a transmission medium, The controller is configured to implement a set of layers and protocols used to support data transmission, and is adapted to negotiate and configure one or more layers and one or more protocols or combinations thereof before the data transmission, Configuration for the one or more layers and one or more protocols or combinations thereof is a response to an attribute negotiated between the access terminal and a wireless network, The controller causes the access terminal to (1) send a first message to the wireless network that includes a plurality of attribute values of the attribute acceptable to the access terminal, and (2) a subset of the plurality of attribute values of the attribute Receive a second message from the wireless network including at least a second message, wherein the subset includes an attribute value of the attribute acceptable to the access terminal and the wireless network, and (3) to the access terminal and the wireless network. The assigned attribute value is selected from the subset, negotiating by assigning an acceptable attribute value to the attribute, The controller is further adapted to implement a set of default layers and protocols. The method of claim 27, One or more configurable layers, a set of one or more configurable protocols, or a combination thereof, maintained for communication, each configurable layer and protocol corresponding to a negotiable attribute. The method of claim 28, The set of default layers and protocols comprises a configuration protocol used to send and receive the first and second messages. The method of claim 29, The first message and the second message are implemented at a session layer of the communication system. The method of claim 30, Wherein each message of the first and second messages comprises a transaction identifier. As an access terminal in a spread spectrum communication system, A controller configured to receive and process data, An encoder connected to the controller and configured to encode processed data from the controller; A modulator connected to the encoder and configured to modulate encoded data from the encoder; And A transmitter connected to the modulator and configured to convert modulated data from the modulator into an analog signal for transmission over a transmission medium, The controller is configured to implement a set of layers and protocols used to support data transmission, and is adapted to negotiate and configure one or more layers and one or more protocols or combinations thereof before the data transmission, Configuration for the one or more layers and one or more protocols or combinations thereof is a response to an attribute negotiated between the access terminal and a wireless network, The controller causes the access terminal to (1) send a first message to the wireless network that includes a plurality of attribute values of the attribute acceptable to the access terminal, and (2) a subset of the plurality of attribute values of the attribute Receive a second message from the wireless network including at least a second message, wherein the subset includes an attribute value of the attribute acceptable to the access terminal and the wireless network, and (3) to the access terminal and the wireless network. The assigned attribute value is selected from the subset, negotiating by assigning an acceptable attribute value to the attribute, The attribute is negotiated over a dedicated channel. As an access terminal in a spread spectrum communication system, Means for receiving and processing data; Means for encoding the processed data; Means for modulating the encoded data; Means for converting the modulated data into an analog signal for transmission over a transmission medium; And Means for negotiating and configuring a set of layers and protocols used to support data transmission between the access terminal and a wireless network, One or more layers, one or more protocols, or a combination thereof, are configurable prior to transmission of the data, The configuration for the one or more layers, one or more protocols, or a combination thereof is in response to an attribute negotiated through the exchange of messages between the access terminal and the wireless network, The means for negotiating and configuring are arranged to (1) transmit a first message from the access terminal to the wireless network, the first message comprising a plurality of attribute values of the attribute acceptable to the access terminal, and (2) from the wireless network. Receive a second message to the access terminal, the second message comprising at least a subset of the plurality of attribute values of the attribute, wherein the subset includes attribute values of the attribute acceptable to the access terminal and the wireless network; 3) an access terminal arranged to assign an attribute value acceptable to the access terminal and the wireless network to the attribute, wherein the assigned attribute value is selected from the subset. The method of claim 33, wherein Means for receiving a forward link signal; Means for demodulating the received forward link signal; And Means for decoding the demodulated signal to produce decoded data, And the means for negotiating and configuring comprises means for configuring one or more of the configurable layers and protocols based on at least a portion of the decoded data. Receiving and processing data; Encoding the processed data; Modulating the encoded data; Converting the modulated data into an analog signal for transmission over a transmission medium; And Negotiating and configuring a set of layers and protocols used to support data transmission between an access terminal and a wireless network, One or more layers, one or more protocols, or a combination thereof, are configurable prior to transmission of the data, The configuration for the one or more layers, one or more protocols, or a combination thereof is in response to an attribute negotiated through the exchange of messages between the access terminal and the wireless network, Said negotiating and configuring comprises: (1) transmitting a first message from a first communication device to a second communication device, said first message comprising a plurality of attribute values of said attribute acceptable to said first communication device, The first and second communication devices are selected from the group comprising the access terminal and the wireless network, and (2) a second message comprising at least a subset of the plurality of property values of the property from the second communication device; Receiving at a first communication device, the subset including an attribute value of the attribute acceptable to the first communication device and the second communication device, and (3) at the first communication device, Assigning an attribute value acceptable to the first communication device and the second communication device to the attribute, wherein the assigned attribute value is selected from the subset , The way. 36. The method of claim 35 wherein Receiving a forward link signal; Demodulating the received forward link signal; And Decoding the demodulated signal to generate decoded data, The negotiating and configuring comprises configuring one or more of the configurable layers and protocols based on at least a portion of the decoded data. 36. The method of claim 35 wherein The attribute is negotiated over a dedicated channel. 36. The method of claim 35 wherein The attribute corresponds to an air interface layer.

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